Mehmet Özgüe Çelik | Engineering | Best Researcher Award

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Mehmet Özgüe Çelik | Engineering | Best Researcher Award

Mersin University | Turkey

Dr. Mehmet Özgür Çelik is a dedicated researcher and academic in the Department of Geomatics Engineering at Mersin University, Türkiye. With a strong academic foundation that includes a Bachelor’s and Master’s degree in Geomatics Engineering from Karadeniz Technical University and a Ph.D. in Remote Sensing and Geographic Information Systems, his work bridges advanced spatial technologies with pressing environmental challenges. His research primarily focuses on Geographic Information Systems (GIS), remote sensing applications, groundwater monitoring, climate change analysis, and land administration systems. Through his scholarly pursuits, Dr. Çelik explores innovative methods for integrating spatial data and satellite imagery to support sustainable resource management, environmental monitoring, and spatial planning. As a Research Assistant, he has contributed to multiple academic projects and publications that advance understanding in geospatial modeling, environmental assessment, and the application of geoinformatics in decision-making processes. His work is distinguished by its interdisciplinary nature, combining technical precision with environmental and societal relevance. Actively involved in academic research communities, Dr. Çelik maintains an active presence on platforms such as ORCID, ResearchGate, Google Scholar, and Publons, where his studies contribute to the global discourse on geospatial science and environmental sustainability. His commitment to leveraging GIS and remote sensing technologies to address challenges related to climate change, land use, and water resources underscores his vision of using spatial intelligence for a more sustainable and data-driven future.

Profile: Orcid | Scopus | Google Scholar

Featured Publications

  • Çelik, M. Ö., Orhan, O., & Kurt, M. A. (2025, October 1–3). Mersin’de iklim değişikliğinin avokado yetiştiriciliğine etkilerinin MaxEnt ile tahmini ve mevcut arazi örtüsü ile karşılaştırılması [Symposium presentation]. TMMOB Harita ve Kadastro Mühendisleri Odası, 20. Türkiye Harita Bilimsel ve Teknik Kurultayı, Ankara, Türkiye.

  • Çelik, M. Ö., Orhan, O., & Kurt, M. A. (2025). Drivers and impacts of climate change: Comprehensive review of natural and anthropogenic forcing with GCM-based projections. Geomatics and Environmental Engineering, 19(5), 71–101.

  • Çelik, M. Ö., Orhan, O., & Kurt, M. A. (2025). Predicting climate change impacts on sub-tropical fruit suitability using MaxEnt: A regional study from Southern Türkiye. Sustainability, 17(12), 5487.

  • Çoruhlu, Y. E., Alemdar, A., & Çelik, M. Ö. (2024). Investigating the possible effects of the authorization of notaries in real estate selling transactions on the land registry system, with Cadastre 2014’s vision and the light of the opinions of the employees of GDLRC. The Black Sea Journal of Sciences, 14(3), 1245–1274.

  • Çelik, M. Ö., Kuşak, L., & Yakar, M. (2024). Assessment of groundwater potential zones utilizing geographic information system-based Analytical Hierarchy Process, Vlse Kriterijumska Optimizacija Kompromisno Resenje, and Technique for Order Preference by Similarity to Ideal Solution methods: A case study in Mersin, Türkiye. Sustainability, 16(5), 2202.

  • Çelik, M. Ö., & Çoruhlu, Y. E. (2021, November). Development of an object-oriented geographical data model for the management of SPEA. In International Conference on Mediterranean Geosciences Union (pp. 271–274).

Saša Milojević | Engineering | Best Researcher Award

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Saša Milojević | Engineering | Best Researcher Award

Faculty of Engineering University of Kragujevac | Serbia

Dr. Saša T. Milojević is a distinguished Serbian scholar and expert advisor with over three decades of academic and industrial experience in mechanical and automotive engineering, specializing in powertrain systems, vehicle maintenance, renewable energy, sustainable transport, and environmental protection. He earned his BSc, MSc, and PhD degrees from the University of Kragujevac, Faculty of Engineering, where he currently serves as an Assistant Professor in the Department of Powertrain and Mobile Systems. Alongside his academic duties, Dr. Milojević works as an expert advisor in the field of technical inspection and homologation testing of vehicles, contributing his expertise to the advancement of vehicle safety and compliance standards. His professional career also includes over five years as Head of Production and Technical Manager in the bus and truck industry, where he gained extensive experience in manufacturing and industrial management. Dr. Milojević has authored more than 100 scientific publications, including journal papers, conference proceedings, book chapters, and edited volumes, reflecting his broad and impactful research output. His work bridges the fields of internal combustion engines, alternative fuels, tribology, and recycling technologies, emphasizing sustainable and energy-efficient mobility solutions. He played a leading role as Consortium Manager in two FP7 projects focusing on innovative low-floor electric and hydrogen-powered minibuses, and as a team leader, he won the regional innovation award for developing Serbia’s first low-floor city bus powered by natural gas. Since 2023, Dr. Milojević has been representing the KG EDU-S research center in the European and USA network for education and research, promoting sustainable development in transport and industry through collaborative international projects. His career stands as a testament to the integration of engineering innovation, education, and sustainability.

Profile: Scoups | Orcid | Google  Scholar 

Featured Publications

  • Skrúcaný, T., Kendra, M., Stopka, O., Milojević, S., Figlus, T., & Csiszár, C. (2019). Impact of the electric mobility implementation on the greenhouse gases production in central European countries. Sustainability, 11(18), 4948.

  • Milojević, S., Glišović, J., Savić, S., Bošković, G., Bukvić, M., & Stojanović, B. (2024). Particulate matter emission and air pollution reduction by applying variable systems in tribologically optimized diesel engines for vehicles in road traffic. Atmosphere, 15(2), 184.

  • Sandra, V., Stojanovic, B., Ivanović, L., Miladinovic, S., & Milojević, S. (2019). Application of nanocomposites in the automotive industry.

  • Milojević, S., Savić, S., Marić, D., Stopka, O., Krstić, B., & Stojanović, B. (2022). Correlation between emission and combustion characteristics with the compression ratio and fuel injection timing in tribologically optimized diesel engine. Tehnički vjesnik, 29(4), 1210–1219. https://doi.org/10.17559/TV-20220322134250

  • Milojević, S., Savić, S., Marić, D., Stopka, O., Krstić, B., & Stojanović, B. (2022). Multi-objective optimization of tribological characteristics for aluminum composite using Taguchi grey and TOPSIS approaches. Tehnički vjesnik, 29(4), 1210–1219.

Qinghua Wei | Engineering | Best Research Article Award

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Qinghua Wei | Engineering | Best Research Article Award

Dr. Qinghua Wei, Northwestern Polytechnical University, China

Dr. Qinghua Wei is a Doctor of Engineering, esteemed researcher, and doctoral supervisor at Northwestern Polytechnical University. Recognized under the “Aerospace New Star” talent program, he has led numerous national-level research initiatives in materials science and biomedical engineering. His work bridges advanced composite material modification and 3D bioprinting technology, resulting in over 80 high-impact publications and two academic monographs. With a strong interdisciplinary approach, Dr. Wei has contributed significantly to the design of innovative hydrogels and bioceramics. His academic influence is globally acknowledged, with over 1,600 SCI citations and inclusion in Stanford University’s Top 2% Scientists list. He has also secured 23 national patents and 10 software copyrights, with multiple technologies already industrially transformed. Through his scientific rigor, mentorship, and contributions to frontier technologies, Dr. Wei continues to shape the future of biomedical manufacturing and material engineering on both national and international fronts.

Publication Profile

orcid

Education

Dr. Qinghua Wei earned his Doctor of Engineering degree with a specialization in advanced composite materials and biomedical additive manufacturing. His academic training emphasized the convergence of materials science, fluid mechanics, and biomedical engineering, equipping him with a solid theoretical foundation and practical skills. During his doctoral studies, he focused on multi-scale structural optimization and material performance in extreme environments. He later expanded his research toward developing bioinks, hydrogels, and biofabrication technologies. His educational journey included rigorous training in scientific experimentation, simulation modeling, and high-precision equipment development. Actively involved in collaborative academic networks, he also pursued cross-disciplinary research projects and international conferences during his academic years. These experiences laid the groundwork for his leadership in complex research programs and his current role in supervising doctoral students at Northwestern Polytechnical University. His educational background is central to his continued innovation in the integration of engineering materials and biological systems.

Experience

Dr. Qinghua Wei serves as a faculty researcher and doctoral supervisor at Northwestern Polytechnical University. Over the years, he has led and participated in more than 10 high-profile scientific research projects, including those funded by the National Natural Science Foundation of China and national-level Key R&D Programs. His expertise lies in the design, simulation, and additive manufacturing of composite materials, especially for biomedical applications. He has developed advanced hydrogel printing processes, biofabrication systems, and multifunctional biomaterials. As a senior researcher, Dr. Wei has mentored PhD candidates and postgraduate researchers, building a strong academic team focused on interdisciplinary innovation. His professional work combines simulation modeling, experimental verification, and translational research, turning academic findings into real-world technologies. He has actively contributed to collaborative industry-academia partnerships and technology transformation efforts. With multiple accolades and patents, Dr. Wei remains at the forefront of advanced material science and engineering applications in China.

Honors and Awards

Dr. Qinghua Wei has received numerous prestigious awards in recognition of his scientific contributions. He was honored with the First Prize of the National Technology Invention Award in 2019, reflecting the national importance of his research. Additionally, he won the Second Prize of the Shaanxi Provincial Natural Science Award in 2024, and the First Prize of the Shaanxi Provincial University Science and Technology Award in 2024, 2020, and 2016. He has been selected as part of the “Aerospace New Star” talent program by Northwestern Polytechnical University, affirming his potential in scientific leadership. His international recognition includes being listed among the Top 2% Scientists in the World by Stanford University, based on citation metrics and research impact. Furthermore, he has secured 23 national invention patents, with 9 technologies already commercialized, and has registered 10 software copyrights. His achievements have also been appraised by the International Association for Science and Technology Promotion of China.

Research Focus

Dr. Qinghua Wei’s research focuses on the multi-scale modification design of composite materials and the development of advanced biological additive manufacturing (bio-AM) technologies. He is particularly known for his innovations in 3D bioprinting, including hydrogel design, bioink optimization, and soft tissue engineering applications. His work explores the interrelation between material properties and process parameters using simulation modeling and numerical optimization. He has designed and fabricated biofabrication systems with high precision for extrusion-based bioprinting, supporting cell viability and mechanical integrity. In materials science, Dr. Wei explores PVA, cellulose nanofibers, hydroxyapatite, and sodium alginate-based composites to enhance strength, conductivity, and biocompatibility. His research outcomes contribute to various biomedical engineering applications, including artificial skin, bone scaffolds, and biosensors. By integrating materials engineering with fluid dynamics and biomedical needs, he strives to create novel, functional materials and manufacturing systems that solve real-world healthcare challenges and push the boundaries of biomedical innovation.

Publications

  1. 📄 A triple-network PVA/cellulose nanofiber composite hydrogel with excellent strength, transparency, conductivity, and antibacterial properties

  2. 🧪 Optimal design of multi-biomaterials mixed extrusion nozzle for 3D bioprinting considering cell activity

  3. 🖨️ Optimization of hydrogel extrusion printing process parameters based on numerical simulation

  4. 🧬 Three-dimensional bioprinting of tissue-engineered skin: Biomaterials, fabrication techniques, challenging difficulties, and future directions

  5. 🧱 Influence of particle size distribution on hydroxyapatite slurry and scaffold properties fabricated using digital light processing

  6. 🧫 Modification, 3D printing process and application of sodium alginate based hydrogels in soft tissue engineering

  7. 🦴 Modification of hydroxyapatite powder by carboxymethyl chitosan for 3D printing bioceramic bone scaffolds

  8. ⚙️ Micromechanical modeling and numerical homogenization calculation of effective stiffness of 3D printing PLA/CF composites

  9. 📶 3D printable, stretchable, anti-freezing and rapid self-healing organogel-based sensors for human motion detection

  10. 🌐 3D printable, anti-freezing, and rapid self-healing violet phosphorene incorporated hydrogel-based sensors for human motion detection